低氧环境中Rac1调节破骨细胞功能的实验研究

doi:10.12439/kqhm.1005-4979.2024.01.002

摘要/Abstract

摘要：

目的：探究低氧条件下低氧诱导因子-1α（hypoxia-inducible factor-1α，HIF-1α）通过调控Rac1对细胞骨架的影响及其调节破骨细胞骨吸收功能变化的作用。方法：利用氯化钴（cobalt dichloride，CoCl₂）刺激小鼠单核细胞系RAW264.7建立体外低氧破骨细胞培养体系。采用sRANKL条件培养液诱导RAW264.7细胞分化，利用CoCl₂模拟低氧环境刺激细胞，7 d后行TRAP染色；利用实时定量聚合酶链反应（real-time quantitative polymerase chain reaction，RT-qPCR）、细胞免疫荧光检测和蛋白质印迹法（Western blotting）检测低氧下破骨细胞表达HIF-1α、Rac1及破骨细胞相关表面标志物与封闭带的情况；同时检测HIF-1α条件性敲除细胞株RAW264.7及Rac1活性抑制剂对相同条件下破骨细胞相关基因和封闭带的影响。结果：低氧环境可促使RAW264.7诱导形成的破骨细胞体积增大、骨吸收能力增强（P<0.01）。低氧组破骨细胞表达的Rac1 mRNA水平升高，且封闭带表达显著（P<0.001）。HIF-1α KO RAW264.7细胞诱导形成破骨细胞体积减小，HIF-1α表达显著降低，Rac1也随之降低（P<0.001）；同时，抑制剂组诱导生成的破骨细胞体积减小，HIF-1α表达保持不变，封闭带形成异常（P<0.01）。结论：小鼠单核细胞系RAW264.7在低氧环境下可通过HIF-1α调控Rac1来影响其所形成的破骨细胞细胞骨架，进而改变破骨细胞的骨吸收能力。

关键词: 细胞骨架, 低氧诱导因子-1α, RAW264.7细胞, Rac1

Abstract:

Objective: To investigate the effect of hypoxia-inducible factor-1α (HIF-1α) on the changes of osteoclast bone resorption capacity by regulating Rac1 on cytoskeleton under hypoxic environment. Methods: The hypoxia culture system was established by stimulating mouse mononuclear cell line RAW264.7 with cobalt dichloride (CoCl₂) in vitro. The differentiation of RAW264.7 cells was induced by sRANKL conditioned culture medium and stimulated by CoCl₂ simulated hypoxic environment, and TRAP staining was performed after 7 days; real-time quantitative polymerase chain reaction (RT-qPCR), cellular immunofluorescence assay and Western blotting were used to detect the expression of HIF-1α KO Rac1, osteoclast-related surface markers and closure zones in RAW264.7 under hypoxia. Simultaneously, HIF-1α conditional knockout cell line RAW264.7 and the effect of the inhibitor of Rac1 on the expression of osteoclast-related genes and closure zones in RAW264.7 under the same conditions were detected.Results: Hypoxia could increase the volume of RAW264.7 induced osteoclasts and enhance bone resorption capacity (P<0.01). The level of Rac1 mRNA expressed by osteoclasts in hypoxia group was increased, and the expression of closure zones were significant (P<0.001). The volume of osteoclasts induced by HIF-1α KO RAW264.7 cells decreased, the expression of HIF-1α was significantly decreased, and Rac1 was also decreased (P<0.001); meanwhile, the volume of osteoclasts decreased in the inhibitor group, the expression of HIF-1α remained unchanged, and the closure zones formed abnormally (P<0.01). Conclusion: Under hypoxia, mouse mononuclear cell line RAW264.7 can regulate Rac1 through HIF-1α protein to affect the cytoskeleton of osteoclasts, and then change the bone resorption capacity of osteoclasts.

Key words: cytoskeleton, hypoxia-inducible factor-1α, RAW264.7 cells, Rac1

中图分类号:

R782

顾家泓, 田原野, 康非吾. 低氧环境中Rac1调节破骨细胞功能的实验研究[J]. 《口腔颌面外科杂志》, 2024, 34(1): 14-21.

GU Jiahong, TIAN Yuanye, KANG Feiwu. Experimental study of Rac1 regulating osteoclast function in hypoxic environment[J]. 《Journal of Oral and Maxillofacial Surgery》, 2024, 34(1): 14-21.

https://journal06.magtech.org.cn/Jweb_joms/CN/Y2024/V34/I1/14

图/表 5

表1 引物序列

Table 1 Primers sequence

基因	正向序列(5'-3')	反向序列(5'-3')
HIF-1α	GAATGAAGTGCACCCTAACAAG	GAGGAATGGGTTCACAAATCAG
CTSK	CAGCAGAGGTGTGTACTATG	GCGTTGTTCTTATTCCGAGC
MMP-9	TGAGTCCGGTCTTCCGAGTT	CCACGTGCGGGCAGTAA
TRAP	CACTCCCACCCTGAGATTTGT	CATCGTCTGCACGGTTCTG
Rac1	GCCGTGGGGAAGGAAAAGT	GTGGCTAGGTACTGAACAAAGAG
β-actin	GAAATCGTGCGTGACATCAAA	TGTAGTTTCATGGATGCCACAG

图1 体外模拟低氧状态下破骨细胞的生成情况与相关标志物mRNA的表达情况 A、B．对照组与低氧组破骨细胞TRAP染色图，低氧组破骨细胞体积较大，形态相对不规则(×4，×10)；C.RT-qPCR检测HIF-1α、MMP-9、TRAP、CTSK mRNA相对表达量。**表示P<0.01，***表示P<0.001，与对照组相比。

Figure 1 Osteoclast generation and mRNA expression of related markers in vitro under hypoxia

图2 生物信息学分析 A.热图；B.火山图。

Figure 2 Bioinformation analysis

图3 HIF-1α 条件性敲除 RAW264.7所形成破骨细胞的生成情况 A、B.破骨细胞生成情况（×4，×10）及所形成表面积，KO组所形成的破骨细胞体积小，呈卵圆形；C. RT-qPCR检测HIF-1α、Rac1、MMP-9、TRAP、CTSK的mRNA相对表达量；D. Western blotting检测HIF-1α和Rac1蛋白表达水平的定量分析；E、F. 细胞免疫荧光检测结果，肌动蛋白、Rac1蛋白免疫荧光结果（×20），白色箭头所指为破骨细胞封闭带，绿色信号为鬼笔环肽信号，红色信号为Rac1蛋白阳性信号，蓝色信号为DAPI核染信号。*表示P<0.05，**表示P<0.01，***表示P<0.001，与对照组比较。

Figure 3 Osteoclast formation from HIF-1α conditional knockout of RAW264.7

图4 低氧抑制RAW264.7内Rac1使破骨吸收能力降低 A、B.破骨细胞生成情况（×4，×10）及所形成表面积，抑制剂组所形成破骨细胞的体积较小，抑制剂低氧组所形成的相对较大。C. RT-qPCR检测HIF-1α、Rac1、MMP-9、TRAP、CTSK mRNA相对表达量。D. Western blotting检测HIF-1α和Rac1蛋白表达水平的定量分析。E、F. 细胞免疫荧光检测结果，肌动蛋白、Rac1蛋白免疫荧光结果（×20），白色箭头所指破骨细胞封闭带，绿色信号为鬼笔环肽信号，红色信号为Rac1蛋白阳性信号，蓝色信号为DAPI核染信号。*表示P<0.05，**表示P<0.01，***表示P<0.001，与对照组比较；##表示P<0.01，###表示P<0.001，与抑制剂组比较。

Figure 4 Inhibition of Rac1 in RAW264.7 decreased osteoclast absorbance

参考文献 23

[1]	Feng X, McDonald JM. Disorders of bone remodeling[J]. Annu Rev Pathol, 2011, 6: 121-145. doi: 10.1146/annurev-pathol-011110-130203 pmid: 20936937
[2]	Haga RB, Ridley AJ. Rho GTPases: Regulation and roles in cancer cell biology[J]. Small GTPases, 2016, 7(4): 207-221. pmid: 27628050
[3]	Etienne-Manneville S, Hall A. Rho GTPases in cell biology[J]. Nature, 2002, 420(6916): 629-635. doi: 10.1038/nature01148
[4]	Razzouk S, Lieberherr M, Cournot G. Rac-GTPase, osteoclast cytoskeleton and bone resorption[J]. Eur J Cell Biol, 1999, 78(4): 249-255. doi: 10.1016/S0171-9335(99)80058-2 pmid: 10350213
[5]	Bromley M, Woolley DE. Chondroclasts and osteoclasts at subchondral sites of erosion in the rheumatoid joint[J]. Arthritis Rheum, 1984, 27(9): 968-975. doi: 10.1002/art.v27:9 URL
[6]	Tella SH, Gallagher JC. Biological agents in management of osteoporosis[J]. Eur J Clin Pharmacol, 2014, 70(11): 1291-1301. doi: 10.1007/s00228-014-1735-5 pmid: 25204309
[7]	Krzeszinski JY, Wan YH. New therapeutic targets for cancer bone metastasis[J]. Trends Pharmacol Sci, 2015, 36(6): 360-373. doi: 10.1016/j.tips.2015.04.006 pmid: 25962679
[8]	Teitelbaum SL. The osteoclast and its unique cytoskeleton[J]. Ann N Y Acad Sci, 2011, 1240: 14-17. doi: 10.1111/nyas.2011.1240.issue-1 URL
[9]	张蓉, 田宗成, 商澎. 破骨细胞伪足小体的结构和功能[J]. 中国细胞生物学学报, 2012, 34(2): 179-184.
[10]	Bunn HF, Poyton RO. Oxygen sensing and molecular adaptation to hypoxia[J]. Physiol Rev, 1996, 76(3): 839-885. pmid: 8757790
[11]	Morwenna S, Ratcliffe WP. Mammalian oxygen sensing and hypoxia inducible factor-1[J]. Int J Biochem Cell Biol, 1997, 29(12): 1419-1432. doi: 10.1016/S1357-2725(97)00129-5 URL
[12]	Wenger RH, Gassmann M. Oxygen(es) and the hypoxia-inducible factor-1[J]. Biol Chem, 1997, 378(7): 609-616. pmid: 9278140
[13]	Semenza GL. Hypoxia-inducible factor 1 and the molecular physiology of oxygen homeostasis[J]. J Lab Clin Med, 1998, 131(3): 207-214. pmid: 9523843
[14]	Kolar P, Gaber T, Perka C, et al. Human early fracture hematoma is characterized by inflammation and hypoxia[J]. Clin Orthop Relat Res, 2011, 469(11): 3118-3126. doi: 10.1007/s11999-011-1865-3 URL
[15]	Ridley AJ, Paterson HF, Johnston CL, et al. The small GTP-binding protein rac regulates growth factor-induced membrane ruffling[J]. Cell, 1992, 70(3): 401-410. doi: 10.1016/0092-8674(92)90164-8 pmid: 1643658
[16]	宋瑞龙. OPG对破骨细胞分化过程中细胞骨架的影响及其分子机理[D]. 扬州: 扬州大学, 2014.
[17]	Croke M, Ross FP, Korhonen M, Williams DA, et al. Rac deletion in osteoclasts causes severe osteopetrosis[J]. J Cell Sci, 2011, 124(Pt 22): 3811-3821. doi: 10.1242/jcs.086280 pmid: 22114304
[18]	Turcotte S, Desrosiers RR, Béliveau R. HIF-1alpha mRNA and protein upregulation involves Rho GTPase expression during hypoxia in renal cell carcinoma[J]. J Cell Sci, 2003, 116(Pt 11): 2247-2260. pmid: 12697836
[19]	Du J, Xu R, Hu ZZ, et al. PI3K and ERK-induced Rac1 activation mediates hypoxia-induced HIF-1α expression in MCF-7 breast cancer cells[J]. PLoS One, 2011, 6(9): e25213. doi: 10.1371/journal.pone.0025213 URL
[20]	Güntert T, Gassmann M, Ogunshola OO. Temporal Rac1–HIF-1 crosstalk modulates hypoxic survival of aged neurons[J]. Brain Res, 2016, 1642: 298-307. doi: S0006-8993(16)30154-8 pmid: 27018294
[21]	Weidemann A, Breyer J, Rehm M, et al. HIF-1α activation results in actin cytoskeleton reorganization and modulation of Rac-1 signaling in endothelial cells[J]. Cell Commun Signal, 2013, 11(1): 80. doi: 10.1186/1478-811X-11-80
[22]	Hirota K, Semenza GL. Rac1 activity is required for the activation of hypoxia-inducible factor 1[J]. J Biol Chem, 2001, 276(24): 21166-21172. doi: 10.1074/jbc.M100677200 pmid: 11283021
[23]	Lu CY, Saless N, Wang XD, et al. The role of oxygen during fracture healing[J]. Bone, 2013, 52(1): 220-229. doi: 10.1016/j.bone.2012.09.037 pmid: 23063782

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